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Wildlife Conservation Marwell Wildlife Colden Common, Winchester Hampshire SO21 3JH Website: www.marwell.org.uk Email: [email protected] Registered Charity No: 275433 Our mission: Marwell is dedicated to the conservation of wildlife and other natural resources. Our vision: Living in balance with nature. Our aims: • Conserve species and their habitats, both locally and globally. • Further understanding and inspire care for the natural world. • Undertake and share our results from scientific studies. • Understand our impacts and improve our environmental performance. Our brand promise: Connecting people with nature Wildlife Conservation Contents Introduction Is there a need for conservation? Value of biodiversity Loss of biodiversity 1. Habitat loss 2. Pollution and nutrient loading 3. Over-exploitation 4. Climate change 5. Alien species Marwell’s role in conservation 1. 2. 3. 4. Conserve species and their habitats, locally and globally Inspire care for the natural world Undertake and share our results of scientific studies Improve our environmental performance and promote sustainable living Can zoological collections play an active role in conservation? Case study: Cheetah International cooperation Endangered species breeding programme Selective breeding Breeding successes at Marwell Conservation case study: Cheetah Factors affecting cheetah populations Habitat loss Decline in prey species Interspecific competition Direct persecution Low genetic diversity Current protection Marwell and cheetah conservation Classification and Marwell Carl Linnaeus Classification Hierarchical system Example of classification: Ocelot Scientific name The importance of classification to Marwell Issues with classification Bibliography Wildlife Conservation Introduction The aim of this booklet is to give you an insight into the work that zoological parks and conservation charities, like Marwell Wildlife, are trying to achieve and for you to explore some of the dilemmas that are faced by conservationists in the field. Is there a need for conservation? Marwell Wildlife is dedicated to the conservation of biodiversity and other resources as we feel that there is a need to conserve the wealth of life on Earth which includes all living organisms, biological communities and ecosystems. Biodiversity matters as it is essential to all life, including our own, it provides us with food, water and oxygen, regulates the climate and some forms of pollution. We feel there is a need for conservation as there have been 809 documented extinctions since 19481. Also another 66 species have become extinct in the wild but exist in captivity1. This is an alarming rate, as the fossil record shows us that the natural rate of background extinctions is approximately 1 species every 4 years. This means that the current rate of extinction is much greater than the natural rate and it is very probable that the majority of these are the result of human activities. Currently we have documented an estimated 1.8 million¹ species, however it is very likely that there are many more species that are undiscovered and we do not know the true extent of the world’s biodiversity. In order for us to monitor the species we are aware of, the IUCN evaluates populations and categorises them depending on their health of their numbers and the threats affecting them. They have assessed 2.7%1 of these named species and have placed them into nine categories ranging from extinct to not evaluated. These species lists are updated and published every two years as the IUCN Red List. Here at Marwell Wildlife we have a number of species of conservation concern. The list below shows the IUCN categories and examples of species. You can see some of these species at Marwell. Extinct: Extinct in the Wild (EW): Critically Endangered (CR): Endangered (EN): Vulnerable (VU): Near Threatened (NT): Least Concern (LC): Data Deficient: Not Evaluated: Quagga (Equus quagga quagga) Scimitar horned oryx (Oryx dammah) Przewalski’s horse (Equus caballus przewalskii) Siamang gibbon (Symphalangus syndactylus) Pale heath violet (Viola lactea) White rhino (Ceratotherium simum simum) Meerkat (Suricata suricatta) Chapman’s zebra (Equus burchellii chapmanni) - an extremely large category The work of the IUCN enables the implementation of conservation strategies and protection agreements in order to support remaining populations. CITES is the Convention on International Trade in Endangered Species (flora and fauna) which aims to control the trade of species and their products worldwide. In order to be party to this convention a country must sign up to it. Currently 5,000 species of animal and 28,000 species of plant are protected by CITES under three appendices2. Appendix I: lists the most endangered species (plants and animals) on the IUCN Red List. As these species are threatened with extinction their trade is prohibited unless permission has been granted by CITES2. An example species is the red panda (Ailurus fulgens fulgens). Wildlife Conservation Appendix II: lists the species that are not currently threatened with extinction but may become so if their trade is not strictly controlled therefore export permits must be acquired before specimens can be traded internationally2. Hartmann’s mountain zebra (Equus zebra hartmannae) are one subspecies listed in this appendix. Appendix III: this refers to lists that have been requested by Parties (signatories to CITES) that already control the trade of certain species to prevent unsustainable or illegal exploitation2. The ring-necked parakeet (Psittacula krameri) is listed in Appendix III under the request of Ghana as trade of this bird from Ghana is prohibited and therefore certification of origin is required. Value of biodiversity Biodiversity includes all living organisms including their genetic variation and the variety of habitats in which they are found. Biodiversity matters for a number of reasons as it is essential for all life, especially our own. We place an intrinsic value upon the diversity of life as it provides us with aesthetic pleasure and thereby enhances our own recreation and leisure activities. This intrinsic value ranges from the grass on which to play sports and sunbathe on to breathtaking views and wildlife watching. We utilise a wide range of products including food items and medicinal products. Examples of these products grow in our tropical house and include plants such as Ananas sativa, which produces pineapples, and the rosy periwinkle (Catharanthus roseus) which contains alkaloids used in the treatment of cancers such as childhood leukaemia. These products are not only beneficial to individuals today but also to individuals in the future as we learn more about how they can be used and therefore they support the global economy. On an ecosystem level, biodiversity not only provides food for species at all trophic levels but also provides oxygen, fresh water and assists in climate regulation. Loss of biodiversity Unfortunately, many of the species that form the world’s biodiversity are under threat from extinction from human activities that are causing problems such as habitat loss, pollution and climate change. Whilst some species are affected by one main threat, many are threatened by a combination of human impacts. There are 5 main threats/reasons that are currently causing the loss of biodiversity especially in terms of species diversity, the genetic diversity of a species and their habitats. 1. Habitat loss: Habitat loss occurs in all habitats and can be linked to a number of human activities. Many are aware of the loss of rainforest due to logging however few think about the loss of the frozen packice in the Arctic which is reducing the area over which species, such as the polar bear, can hunt. • The cotton-top tamarin, Saguinus oedipus, is now classed as critically endangered as it’s population has decreased by 80% in the last 18 years due to habitat destruction. This has resulted from colonisation by a growing human population and clearance of forest for agricultural activities. 75% of the tamarins natural habitat has been lost and the remainder has become severely fragmented3. • The Hula painted frog, Discoglossus nigriventer, from Israel is now extinct due to marsh drainage in 1950’s to eradicate malaria and provide land for agriculture4. 2. Pollution and nutrient loading: Pollution is the result of any contaminant (pollutant) that affects the natural biotic and abiotic environment. This includes air pollution, light pollution, thermal pollution, soil contamination, littering, water pollution, space pollution and radioactive pollution. Any form of pollution can affect the environment in which it is initially released and also those further a-field. For example pesticides Wildlife Conservation and other toxic contaminants are released into the environment at a source but these can affect species that are not found in the local area. Contaminants can be carried along water currents, in the air and once they enter the food chain they bioaccumulate affecting all species but in particular the top carnivores as these contaminants are stored in the tissues. • Research into polar bears has revealed the presence of high levels of contaminants such as DDT and PBDE, to which their environment has never been directly exposed, in their tissues5. These contaminants can affect the endocrine system thereby reducing fertility, decreasing the strength of immune systems and interrupting neural pathways5. • The boreal felt lichen, Erioderma pedicellatum, like many lichens is extremely sensitive to air pollution. The global population of this lichen, found mostly in Canada, has decreased by 80% thereby making this species critically endangered6. • The white-rumped vulture, Gyps bengalensis, is critically endangered as the result of feeding on carcasses that had been treated with a veterinary drug which is toxic to this bird species7. 3. Over-exploitation: The over-exploitation of species occurs due to their usefulness to us for a wide variety of purposes including as food sources, manufacturing products, medicinal aids, agricultural uses, industrial uses, entertainment/media exploitation, the pet trade, as ornaments and as energy sources. The ways in which we exploit the world’s biodiversity are endless and whilst some use is sustainable, most is not thereby impacting upon the diversity of the biotic and abiotic environment. • Unfortunately, human choices tend to determine the future of some species as despite our understanding surrounding the threats to these species, we continue as if there was no issue at all. An excellent example of this surrounds our wish to eat specific fish species such as North sea cod (vulnerable) and blue fin tuna (critically endangered). We continue to harvest these species even though we know that it is unsustainable just because we want to eat them. 4. Climate change: The extent to which human activities have influenced the natural change in climatic conditions is debatable however it is clear that a number of forms of pollution have influenced changes within our climate. These changes include temperature rises and alterations to weather patterns. Human populations can be dramatically impacted by some of these changes, however other species are far more sensitive to the more delicate changes such as those of temperature. • A major threat to all coral species is that of global climate change as it leads to bleaching and therefore increases the susceptibility of these species to disease. Coral bleaching refers to the loss or reduction of the symbiotic zooxanthellae (microscopic plants) that reside within the coral and can be caused by variations in sea temperature and solar irradiance. 5. Alien species: Any species that is introduced into a country or habitat from which it does not originate is an alien species. The impact of these species varies greatly as they could impact upon food webs, the diversity of species or even influence the genetic diversity of a species if they can interbreed. Some species are introduced into environments in order to act as biological controls, others have escaped into the wild from captivity, and some have been incidentally released. • The most notable example of biological control which has adversely affected an entire genus is that of the Partulid snails. 72% of the Partula species in Polynesia have become extinct due to the introduction of the carnivorous wolf snail (Euglandina rosea) which was introduced in 19758. The wolf snail was introduced as a control measure to reduce the spread of the African giant snail (Achatina fulica) that had been brought to the islands as a food species. Unfortunately, the wolf snails prefer to eat the Partulid snails and those Wildlife Conservation • species that are not already extinct are now extinct in the wild and therefore only survive in captivity8. Unwanted exotic pets can directly or indirectly impact upon the biodiversity of a habitat. For example the red-eared terrapins, Trachemys scripta elegans, from Central America became very popular pets due to the cartoon Teenage Mutant Ninja Turtles, however, they demonstrate a common problem - many exotic pet owners do not find enough information about their chosen pet before they buy it. Sooner or later they realise that for a variety of reasons their chosen pet is not suitable and they no longer want it. Many red-eared terrapins have been indiscriminately released into ponds and lakes throughout Britain. They are voracious carnivores and have proceeded to decimate the numbers of indigenous wildlife, as a result of this the EU has banned the import of these animals. The biodiversity concept model The diagram below shows a concept model that shows what we mean by biodiversity and all the elements that come together to provide a strategy for conservation. Wildlife Conservation Marwell’s Role in Conservation Marwell Wildlife is dedicated to the conservation of biodiversity and other natural resources. Our vision is to live in balance with nature and to achieve this we have four aims: 1. Conserve species and their habitats, locally and globally The best way to conserve biodiversity is to maintain existing habitats. However, many places have already been damaged by human activities and need to be restored and managed to enhance their value to wildlife. Through our British Wildlife programme we seek to make a significant contribution to the conservation of biodiversity on our doorstep in Hampshire and the surrounding counties of southern England. Eelmoor Marsh is a site close to Farnborough, which includes a variety of habitats such as lowland heath, grassland and bog/mire; therefore this site is both nationally and internationally important. Lowland heath is currently a priority for nature conservation because it is a rare and threatened habitat, as over 80% of has been lost in Britain since the 18009. Eelmoor Marsh is protected under National and European legislation. It has been designated a SSSI (Site of Special Scientific Interest), originally due to the mixture of habitats but now also due to the variety of invertebrates especially the dragonflies, butterflies and beetles that have returned due to the restoration. It is an SPA (Special Protected Area) for birds due to the presence of breeding pairs of nightjar, Dartford warbler and woodlark. As it is a refuge for over 360 species of conservation concern it has been designated as a SINC (Site of Importance for Nature Conservation). Marwell have been working with the site owner for over 10 years in the restoration of habitat and management of the site. The habitat management and restoration programme includes the use of particular species. Highland cattle are used on a range of the habitats, as they graze to a certain height and also keep the birch and scrub below seed-bearing height, thereby keeping them under control. The Przewalski’s horses graze specific species to a lower height so they are used to manage the grassland. Physical and mechanical management is also needed in balance with the grazers. This management involves the clearance of scrub areas, clear-felling of the pines and also, as the animals are at a low stocking density, grassland areas are mown. This management allows the botanical species to diversify in the grassland to include herbs and orchids. Thereby allowing rare species such as the previously absent yellow bartsia, early marsh orchid and pale heath violet to increase. Populations of many species have become so small that they need a lot of help to secure their future. Marwell has participated in the breeding and release of sand lizards (Lacerta agilis) since 1989. Sand lizards are the UK’s largest and rarest lizard, and are protected under National and European Law. We breed between 50 and 100 sand lizards each year. Most recently in 2009, 65 Marwell bred sand lizards were released into protected heathland sites in Surrey and Dorset. This was done in partnership with Amphibian and Reptile Conservation10 as they coordinate the release as sand lizards from a range of breeding facilities are used at release sites in order to maximise genetic diversity. The once abundant scimitar-horned oryx was declared as extinct in the wild by the IUCN in 2000 due to over-hunting, competition with domestic livestock and fragmentation of their habitat; therefore they only exist today due to breeding programmes such as the one Marwell is involved in. Due to the success of the captive breeding programme there are now approx 200 captive bred scimitar-horned oryx in protected areas in Tunisia. The reintroductions began in 1985 with 10 oryx from Marwell and Edinburgh Zoo (co-ordinated by ZSL). These were released into Bou Hedma National Park. In 1999 and 2007, Marwell co-ordinated the release of the scimitar-horned oryx from various European collections into different protected areas in Tunisia. These populations are Wildlife Conservation currently being monitored. Reintroductions involve various organisations, are costly, complex and require a lot of expertise along with global collaboration. For further details on the scimitar horned oryx please refer to the conservation pages on our website11. Although difficult, re-introductions involving Marwell have also been successful for cheer pheasants (to the Himalayan foothills in Pakistan), golden lion tamarins (to a reserve in the Brazilian rainforest), Przewalski’s horses (to a reserve in Hungary), natterjack toads and reddish buff moths (to sites in the south of England). 2. Inspire care for the natural world; Education is vital if we are to succeed in conserving the natural world as without interest or understanding, conservation work cannot be self sustaining. Here at Marwell we are very fortunate as we have a fantastic range of resources that allow us to offer first hand learning experiences. We have the Science & Learning Centre where teaching sessions use confiscated animal artefacts and live animal contact. Currently we cater for ages 4 up through to higher education. Out in the park, visitors are able to experience a range of familiar and unfamiliar animals first hand and learn more about them from our interpretation signs. We also run activities and events during the school holidays as we have around half a million visitors each year. In 2010 the Education team was awarded the Learning Outside the Classroom Quality Badge, a nationally recognised benchmark that helps teachers to identify organisations providing high quality education provision. We have also seen a steady growth in the numbers of students visiting us with over 33,000 students in the 2010 summer term. 3. Undertake and share our results of scientific studies; In Northern Kenya, we work with communities who have traditionally made a living through their livestock, but who also recognise the importance of biodiversity for their livelihood. Many have set aside areas of their land for conservation with the aim of deriving benefits from activities such as wildlife tourism. Our field biologists help communities to set up practical, long term monitoring programmes to evaluate the success of their conservation initiatives. This includes designing surveys and providing training for people to monitor vegetation and large mammals. Marwell works closely with Kenyan conservation partners through a joint conservation programme for Grevy’s zebra12. As the last national survey had occurred in 2000, Marwell helped design, plan and carry out a new aerial survey in 2008. This included training partners in the use of software to identify and store individual stripe patterns (similar to human fingerprints) of Grevy’s zebra from digital photos. In 2009, we trialled the use of digital camera traps to see which would be the most suitable to survey Grevy’s zebra and other species in remote locations. Earlier this year, along with our Kenyan partners, we completed a month long survey interviewing local nomadic herdsmen in the far north of Kenya about their attitudes towards the Grevy’s zebra. The herdsmen have a very good knowledge about wildlife and interviewing them is a very efficient means of collecting information over a vast and inaccessible area. By improving our insight into herders’ attitudes through the surveys, and combining this with information from aerial surveys, camera traps and radio collars on the zebras, we now have a more detailed understanding of the issues surrounding the zebra and are therefore able to understand the main threats facing the species, which allows limited conservation resources to be focused towards these areas. For example, one of the main reasons for hunting Grevy’s zebra is to produce traditional medicines from the body fat. If herding communities were able to access modern medicines then the need for hunting would be much reduced. The next step is to develop our understanding on the ranging patterns of these zebra. In Zimbabwe we are helping to understand more about behaviour and distribution of cheetah which are sometimes blamed for killing livestock. This includes promoting ways of protecting livestock without harming cheetah. Wildlife Conservation 4. Improve our environmental performance and promote sustainable living; Our sustainability manager has created environmental management systems so that we have policies and procedures in place for effective environmental management, which includes the prevention of pollution, improvement in our environmental performance and ensuring compliance with legal requirements. We have recycling facilities throughout the park for both visitors and staff and in 2009 we recycled approximately 88% of our waste. As part of our ethical purchasing code we consider where we purchase items from and also consider local sourcing. Our policy is based on the following principles and actions: • Seek to reduce consumption of materials by: reusing rather than disposing of materials, whenever possible • • • • • • • • promoting recycling and the use of recycled materials and repairing existing products. Use of the least environmentally damaging products should be promoted. When new products are obtained, every effort should be made to purchase products made of recycled and recyclable materials. Products at the end of their useful life should be recycled wherever possible, and as a last resort should be disposed of in the most environmentally responsible manner possible. Market products that are safe to use, which make efficient use of resources and which can be reused, recycled, or disposed of safely. Work with our suppliers to minimise the impact of their operations on the environment. Monitor progress and publish an environmental performance report on an annual basis. Develop staff awareness of the environmental issues directing procurement, through the provision of appropriate information and training. Integrate environmental factors into our buying decisions, including taking account of environmental costs and benefits as part of total life cost assessment. The construction of buildings must also be environmentally friendly; therefore Café Graze has lots of natural light, insulation, use of low energy materials and rainwater collection systems (used in our toilets). We have a travel plan so we encourage car sharing and the use of public transport including a free bus service from Eastleigh station on Sundays and Bank holidays. Due to our sustainable management practice we were awarded the ISO14001 which is the international standard for environmental management systems in 2009 and in May this year we were presented with the Sustainable Business Award for the medium business category at the 2009-10 Hampshire and Isle of Wight Sustainable Business Partnership awards13. These aims are further achieved by our investment in individuals and communities. In Kenya there is a delicate balance between the wildlife and the livestock that are reared by the nomadic pastoralists. Marwell is currently involved in the training of the pastoralists, within conservancies, in a range of methods for gathering and recording data from vegetation, bird and mammal surveys in order to gain a better understanding of the impact that livestock have. Marwell also provides laptops and electronic equipment to help gather and analyse the data. Marwell also sponsors MSc students mostly from the less affluent north Kenya region in their research projects. The information gained from these studies is used to help conservancies and develop our understanding. For further details on the work of Marwell Wildlife please refer to our annual report available on our website14. Wildlife Conservation Can zoological collections play an active role in conservation? Many zoological parks once envisaged their animals as only visitor attractions but now many have followed the path taken by conservation charities such as Marwell and now aim to act as arks for threatened species and many, like Marwell, have played a vital role in the breeding and reintroduction of species that are extinct in the wild. There are difficult questions that we need consider: If we have species in zoological parks that, for whatever reason, we cannot put back into the wild then what is their value? Do they then not just become a living museum specimen? Do we breed endangered species because they have a great importance within the biodiversity of their natural habitat or do we do it because it fulfils our pleasure? We now know that to conserve a species in our arks we need more than one male and one female, not just to secure genetic diversity but also recreate environments that stimulate natural social behaviour as many species have complex social systems that influence their reproductive success. If we were to conserve a species initially with only one male and one female we would end up with inbreeding. Currently zoological parks rarely take individuals from the wild therefore the captive populations come from the original individuals that were taken from the larger wild population. This is known as the founder effect as a new population has been established with the zoological community and consequently only a small amount of the overall genetic variation is available. Therefore we must ensure that this variation is maintained and maximised through captive breeding programmes. The aim of a captive breeding programme is to maintain a healthy, self-sustaining population of each chosen threatened species. The key to this is to preserve as much of the initial genetic variation for as long as possible. The genetic variation of a captive population comes from its founders (animals taken from a wild population). It is essential that a as many of the founder’s genes are passed on to future generations if a breeding programme is to succeed. Ideally animals should not breed with their close relatives and where possible, matings should be between entirely unrelated animals. This ensures that the species remains as healthy and as varied as possible. Case study: Cheetah Alongside issues with captive populations resulting from the founder effect, some of the original wild populations, from which captive individuals were taken, were already subject to reductions in genetic diversity due to genetic bottlenecks. The cheetah you see today, Acinonyx jubatus, are the sole member of its genus much like ourselves. Around 20,000 years ago, different species of cheetah roamed across the savannas and plains of Africa, Asia, North America and Europe. Then around 10,000 years ago all but one species became extinct. This was probably the result of extreme climate changes. With the drastic reduction in their numbers, close relatives interbred, and the cheetah became genetically inbred, meaning all cheetahs are now very closely related. Inbreeding occurs when members of the same family or close relatives breed only among themselves. When geneticists looked at the amount of variation within the genes of the cheetah, they found that they exhibit much lower levels of variation than other mammals. In most species, related individuals share about 80% of the same genes but this rises to approx 99% with the cheetah. An experiment used to illustrate this monomorphism (reduced variety of alleles) involves the use of skin grafts. If you take a skin graft from a cheetah and place in it onto another area of its body it will accept the graft. However, if you graft a piece of skin taken from a domestic cat the genetic differences, and hence differences in antigens, results in the graft being rejected. The genetic similarity between individual cheetah is so close that a skin graft from one individual can be placed onto another individual and be accepted not rejected as you would expect. This inbreeding could cause the population to be more susceptible to certain diseases due to the reduction in the diversity of alleles. Issues such as low quality sperm production in males were Wildlife Conservation believed to cause low reproductive success however cheetah in the wild show no issues with reproductive success. Therefore the low quality sperm appears to only be an issue with captive bred populations so it is likely that husbandry can effect breeding success. This example shows that in order to protect a species we must not only look at the genetics of a population but also to the way that we manage them and the husbandry techniques used. International cooperation Individual captive populations are so small that on their own they are of little conservation value. However with large scale cooperation, all the small populations can be considered as one larger, more genetically viable, population. In order for this cooperation to occur there are a number of different organisations involved. The mission of these organisations is to guide and support a community of zoological parks to develop education, research and global conservation. EAZA is a regional organisation enabling effective coordination between European zoos and aquaria. EAZA was formed in 1992 and their “mission is to facilitate cooperation within the European zoo and aquarium community towards the goals of education, research and conservation”15. There are two parts to their breeding programme, the endangered species breeding programme and the European StudBook (record system for individuals of each species). Through this programme individuals are matched together to produce the highest genetic diversity and the European captive populations are managed as a sub population of the overall larger global captive population. This management is the most effective and promotes genetic diversity. On a more local level we also have BIAZA16 who are a similar umbrella organisation to EAZA. Endangered species breeding programme Studbooks allow captive populations to be managed cooperatively. A Studbook keeper is responsible for the collation of data on individuals within a specific species. This includes their sex, date of birth, who the parents are and where they are geographically. Using this data the studbook keeper can make recommendations on the selection of breeding partners and the movement of animals between collections in order to maximise the genetic diversity with the captive population. Marwell co-ordinates stud books for the scimitar-horned oryx, Grevy’s zebra, Hartmann’s zebra and dourocoulis. Studbook reports are available to view on the conservation pages of our website17. As technology has developed the information available to the studbook keeper, and the analysis they can carry out, has progressed. Genetic analysis allows relationships between individuals to be determined. This has been necessary for some species as records dating back to when the founders were first taken from the wild are missing or non-existent. The analysis is carried out on captive groups that are reintroduced to their natural habitat in order to ensure that they have the greatest genetic diversity and are not closely related. SPARKS is a software programme used by studbook keepers to organise pedigree information to produce demographic and genetic data of the captive population. This data helps the keeper know which animals to breed, how many to breed and where to move animals within EAZA member zoos. PM2000 is another software programme that further analyses the genetic information. Selective breeding The allele responsible for white colouration of white tigers originates, like many variations, from a mutation but many collectors preferred this colouration. The white tigers were subjected to a selective breeding process to accentuate the allele responsible for the phenotypic white colouration. Selective breeding has resulted in them becoming inbred and having a very low genetic diversity. This has led to problems such as individuals being cross-eyed and having bone problems. There are also some advantages to selective breeding. As this process leads to individuals being very closely genetically related it is perfect for producing animals such as laboratory rats that need to be as genetically similar as possible for research purposes. Selective breeding is the process which has been used for centuries by humans to select individuals with characteristics that we desire. This mostly relates to livestock and pet breeds including sheep, cattle, snakes, rats, cats and dogs. Wildlife Conservation Benefits and disadvantages to artificial selection for captive breeding The artificial selection of individuals through the captive breeding programme does have its own problems. Sometimes breeding is unsuccessful either due to the animals not cooperating or infertile offspring are produced. A lack of cooperation can sometimes be attributed to husbandry and their captive environment. Also, the captive environment may not be able to sustain the population just like a natural environment. If too many males are produced in groups where the social ration is one male to many females then housing of the surplus males may become an issue. One example of where the artificial environment influenced mating to the detriment of a species was that of the giant panda. They are currently listed as endangered and there have been some issues with a lack of interest in mating and poor reproductive success therefore artifical insemination was used to increase the captive population. More recently, possibly with a greater understanding of the giant panda and their husbandry, they have begun to increase their interest in mating in captivity. Ideally, we would have a greater number of founders who would produce offspring with an equal ratio of males to females. This would then lead to a captive population with an ideal demographic of a population with an equal sex ratio and an even spread of ages. The reality of what we have is very different to the ideal. We have animals that don’t want to cooperate in breeding which could be due to the husbandry conditions and social set-up. There was a lack of understanding regarding the importance of records on the founders which has led to incomplete pedigrees although this no longer causes major problems. Despite these issues many conservation breeding programmes are being successful. For more information on the population management programmes that Marwell is involved in please visit our website17. Breeding successes at Marwell Most species breed successfully and in 2010 we had a number of notable births. Here is some further information about a few of them: • Orana, our female black wildebeest (Connochaetes gnou) gave birth to a healthy baby girl, Layla, in the summer and she is the first black wildebeest to be born at Marwell. • Our Brazilian tapirs (Tapirus terrestris) gave us Quito, a female, in September. • Changes in our Arabian oryx (Oryx leucoryx) group has led to the birth of a male, Ashra. • 2010 was an excellent year for our scimitar-horned oryx (Oryx dammah) as five babies were born in the park, two females and three males. • Three Grevy’s zebra (Equus grevyi) foals were born this summer, one female and two males. • A baby grey-legged dourocoulli (Aotus lemurinus griseimembra) was born in February. • Nsia was born in April and she is our first pure Rothschild giraffe (Giraffe camelopardalis rothschildi) since 1997. • Throughout the year, three Przewalski’s horse (Equus ferus przewalskii) foals were born. • Boomer, our male ostrich (Struthio camelus) is the proud father to eight chicks. Wildlife Conservation Conservation case study: Cheetah (Acinonyx jubatus) Acinonyx jubatus was the only species of cheetah to survive the last ice age 10,000 years ago. This species has over time evolved into several separate sub-species due to geographical isolation either through natural barriers or due to human influences. Today the largest populations are found in South and East Africa, the main stronghold being in South Africa as the East African populations are fragmented19. Cheetah have very large ranges within which they hunt, which is one of the reasons why the populations have been affected by human settlements. Interestingly, the metapopulations of cheetah are found in areas bordering National Parks as cheetah do not do well in protected areas due to interspecific competition. Factors affecting cheetah populations Habitat loss Habitat loss has occurred in many areas with cheetah ranges becoming enclosed or divided due to human settlements. This means that humans have placed obstructions within the cheetah ranges thereby reducing the area in which they can hunt for food and live. Cheetah need a large open space for running down their prey and if buildings are constructed or areas are enclosed then they are unable to hunt successfully. Decline in prey species The prey species and their populations have themselves experienced declines in recent years. This could be due to a number of factors including poaching. This raises a larger problem for the cheetah as they are also experiencing a lot of pressure through interspecific competition. Interspecific competition Cheetah are unsuccessful within protected areas, such as National Parks, due to the large populations of other large carnivores such as lions, leopards and hyenas. The cheetah are capable of catching their own prey but will be bullied away from their prey by these species. This means they are much more successful in areas fringing around national parks. Unfortunately this does mean that they are in areas in which they are not as protected. Direct persecution Cheetah are mostly hunted as they are considered to be a threat to livestock by both pastoralists such as the Masai and the more wealthy livestock ranch owners. Trophy hunting is permitted in some countries such as Namibia. The most vulnerable population in Iran is still persecuted by illegal trophy hunting even though the current population is believed to be less than 100 and is consequently listed on the Red List as critically endangered. The threat of direct persecution is considered to be the easiest of the threats to deal with and resolution of this threat would also have the greatest impact on the populations. Low genetic diversity It was previously thought that the cheetah genetic monomorphism would influence survival especially as there have been problems with cheetah in captive breeding programmes. However, there is no evidence that the low genetic diversity negatively impacts cheetah populations in the wild and in fact most of the populations that are not disturbed have had no issues with breeding and do not seem to have an increased susceptibility to disease as was previously thought. Wildlife Conservation Current protection Currently cheetah are listed on Appendix I of CITES so the trade in products, like pelts, and live individuals is strictly regulated; however currently trophy hunting is permitted in Namibia, Zimbabwe and Botswana. Although, each country has a quota for the number of animals that they are allowed to hunt in this way; annual quotas are 150 for Namibia, 50 for Zimbabwe and 5 for Botswana19. Cheetah are listed as Vulnerable overall on the IUCN Red List. However there are fragmented populations such as the Saharan and Iranian Cheetah that are listed as Critically Endangered due to their extremely low numbers. Marwell and cheetah conservation In 2009 we held the Sprint campaign here at Marwell which allowed us to raise funds for our cheetah project in Kenya and to revamp our cheetah enclosure. The work being carried out in Kenya involves surveying cheetah populations through spoor counts (that is counting their trails or tracks) and with the use of camera traps. A simple strategy to protect livestock from large cats, including the cheetah, is to use a Boma. These are made from thorny shrubs that are put around the livestock thereby preventing the cats from reaching them as they can not go through or jump over the sides of the Boma. In situ education is also a vital part of the conservation strategy and a teaching materials pack called 'Living with Cheetah' has been produced to assist this message in Kenya. Wildlife Conservation Classification and Marwell Carl Linnaeus Carl Linnaeus was also known as Carl von Linne. He was a Swedish naturalist in the 18th Century and is consider by many to be the father of the modern classification system. He devised a system for grouping organisms which he proposed in his work “Systema Naturae”. You may have come across this system of grouping things as either animal, vegetable or mineral. His work is still the basis of the system that we use today. Classification We need to place organisms into an ordered system as there are so many different types of species in the world today. There could possibly be up to 10 million, however we have only named around 1.8 million. When we study living organisms we find that there are many differences and similarities between them and classification helps us to learn more about the relationships between them. Classification is essentially the placing of organisms into groups based on similarities and differences in their characteristics. However, in recent years it has become far more developed and also considers genetic comparisons as well. This has meant that many species that were once put into particular groups have now been placed into separate ones as we have found that even though they have similar physical features they are actually very different genetically. The branch of science that specifically looks at the classification of organisms is known as taxonomy. Throughout your time in school you will have learnt different ways of grouping living things. The most simple way of separating organisms is to group them into animals and plants. To be an animal you need to be made up of many cells, have cells that have specific jobs, have some means of ingesting food and also be able to move whereas to be a plant you need to fulfil the same first two criteria but you also need to be able to photosynthesise food and not be able to move. These criteria are very simplified in order to give a broad spectrum however there are some animals and plants that do not fulfil all of these requirements and yet are placed within these categories. For example, anemones are animals that live attached to rocks and they cannot move, that is they have no form of locomotion during the adult stage of their life cycle, however when they are in the larval stage they form part of the zooplankton and are mobile. Also, there are around 3000 species of non-photosynthetic plants which are nearly all parasitic so they get what they need from their host and are not photosynthetic. Hierarchical system Organisms are classified within a hierarchical system. At the top of the hierarchy are the kingdoms. Linnaeus originally proposed a three kingdom system with everything being either an animal, a vegetable or a mineral. Recently, due to many scientific discoveries, a 5 kingdom system has evolved with Prokaryotes, Protocista, Plantae, Animalia and Fungi. Essentially in this division, all the organisms within a kingdom will work in similar ways. The taxonomic rank below kingdom is phylum. As there is no agreed definition of phylum and there is no agreement on how many phyla there are within any kingdom. Some examples of the phyla within the Animalia kingdom include: • Cnidaria means ‘stinging nettle’ so animals in this phyla are ones with stinging cells such as jellyfish; • Chordata means ‘chord’ so this is the phylum we belong to as we have a cord or spine. All organisms within the Chordata phylum have a cord or spine for all or part of their lifecycle. So all vertebrates belong to this category along with some invertebrates who have share many characteristics with vertebrates but lack a bony skeleton. Examples of Chordata invertebrates are tunicates and lancelets. The taxonomic rank below phylum is called class. Within the Chordata phylum there are the following classes: birds, amphibians, mammals and reptiles. Due to the diverse physiology of fish species there are currently four classes of living fish; hagfishes, lampreys, cartilaginous fish and bony fish. There are also two classes of extinct fish which are subject to regular changes. As there are so many different species within each class, these categories are subdivided further. Wildlife Conservation Each class is subdivided further due to the shear number of different types of organisms however taxonomists rarely agree in which subdivisions organisms should be placed. Genus and species on the other hand are universally accepted which means that we can identify specific living things by their unique scientific name. This is very important for scientists so that studies of certain organisms can be shared and our understanding can be developed. For example when pieces of scientific research are published in journals, the names used for species they refer to, are given in both their common name, for that country, and their scientific name. This means that someone wanting to research that same organism can find the work of another scientist as there is a universal agreement on their scientific name. Example of classification: Ocelot Firstly the kingdom in which the ocelot belongs is Animalia as it is multicellular, it has specialised cells, ingests food and has a means of locomotion. It has a spine so it is in the phylum Chordata. It is warm-blooded, has hair, suckles their young and gives birth to live young so it fits into the class Mammalia. The ocelot has specialised teeth for biting and shearing, and lives primarily on a diet of meat so they belong in the order Carnivora. As they are a carnivore with a short skull and well developed claws they are in the family Felidae. They are a small cat weighing a max of around 16kg so they fit into the genus Felis and their species name is pardalis which refers to its appearance (painted/spots). This means that the scientific name for the ocelot is Felis pardalis. Scientific name This is the only part of classification that the majority of scientists agree and is extremely important to organisations such as Marwell. We need to correctly identify all of our species not just for management of the collection but also to ensure that correct animals are put together for breeding. It is important for studbooks as they refer to animals by their scientific names to ensure that there is no confusion as one species can have many common names. This universal language is also important for research purposes. Sometimes a third name is added such as in the case of our tigers. The Amur leopard is Panthera pardus orientalis as it is a subspecies of the species Panthera pardus. The importance of classification to Marwell So why exactly is classification so important to zoological parks like Marwell? Firstly we are involved in a number of breeding programmes and with them the keeping of studbooks. For breeding programmes to be successful pure species need to be involved and not hybrids as this will adversely alter the genetics of the population, so accurate identification of individuals is needed. Commonly, genetic testing is used to determine the purity of an individual’s breed so that they can participate within the breeding programmes and be registered within a studbook. In terms of our animal collection, we need to ensure that we correctly identify all the individual animals that we have here in the park and keep accurate records. They are all registered with ISIS, the International Species Information System. The following are examples of where correct classification has been essential for the protection of an endangered species. Many years ago we had a group of Asiatic lions that were involved in a breeding programme. Asiatic lions are an endangered species so it would have been ideal to have had our female, Tara, included as part of a breeding programme. However it was found that genetically she had some African lion in her so therefore she was not a pure breed and could not contribute to the programme. Currently have two species of giraffe here at Marwell but we would like to breed pure Rothschild’s giraffes. Before the separate sub-species were recognised, individuals were allowed to breed producing hybrids, particularly individuals of Masai and Rothschild’s sub-species. This has produced a ‘mongrel’ population which poses major issues for conservationists trying to protect the sub-species. Matilda is pure Rothschild giraffe as is her newborn Nsia who was born in April 2010 which is excellent news in terms of conservation of this subspecies. Wildlife Conservation Issues with classification Many species are being reclassified due to more detailed information collected through genetic screening. Also it has been found that in many cases when individuals have initially been classified and given a scientific name they have been considered to be a separate species when actually they are the adult/juvenille stage of another organism. Essentially classification is a very fluid model that constantly changes but for the majority of the time the genus and species names remain universal. Wildlife Conservation Bibliography 1 Vié, J.-C., Hilton-Taylor, C. and Stuart, S.N. (eds.) (2009). Wildlife in a Changing World – An Analysis of the 2008 IUCN Red List of Threatened Species. Gland, Switzerland: IUCN. [http://data.iucn.org/dbtw-wpd/edocs/RL-2009-001.pdf] Accessed 10/12/10 2 The CITES species. [http://www.cites.org/eng/disc/species.shtml] Accessed 05/04/10 3 Savage, A. & Causado, J. 2008. Saguinus oedipus. In: IUCN 2010. IUCN Red List of Threatened Species. Version 2010.4. [http://www.iucnredlist.org/apps/redlist/details/19823/0] Accessed 10/12/10 4 Theodore Papenfuss, Ahmad Disi, Steven Anderson, Sergius Kuzmin, Avital Gasith, Riyad A. Sadek, Yehudah Werner 2004. Discoglossus nigriventer. In: IUCN 2010. IUCN Red List of Threatened Species. Version 2010.4. [http://www.iucnredlist.org/apps/redlist/details/6715/0] Accessed 6/1/11 5 Marren, P (Monday 16th January 2006) Polar bears: Walking on thin ice. The Independent online. [http://www.independent.co.uk/environment/polar-bears-walking-on-thin-ice523207.html] Accessed 8/1/11 6 Scheidegger, C. 2003. Erioderma pedicellatum. In: IUCN 2010. IUCN Red List of Threatened Species. Version 2010.4.[http://www.iucnredlist.org/apps/redlist/details/43995/0] Accessed 6/1/11 7 2010. Gyps bengalensis. In: IUCN 2010. IUCN Red List of Threatened Species. Version 2010.4.[http://www.iucnredlist.org/apps/redlist/details/144350/0] Accessed 6/1/11 8 Bailie, J.E.M., Hilton-Taylor, C. and Stuart, S.N. (eds.) (2004) IUCN Red List of Threatened Species. A Global Assessment. IUCN, Gland, Switzerland and Cambridge, UK. 9 Forestry Commission (unknown) Lowland heath. [http://www.forestry.gov.uk/forestry/lowlandheath] Accessed 10/1/11 10 For information on Amphibian and Reptile Conservation organisation see www.arc-trust.org 11 Gilbert, T. and Woodfine, T. (eds) (2004) The biology, husbandry and conservation of scimitar-horned oryx (Oryx dammah). Available online at http://www.marwell.org.uk/downloads/biology_husbandry_conservation_SHO_2004 .pdf 12 Marwell Wildlife (2010) Grevy’s zebra success. [http://www.marwell.org.uk/grevyszebrasuccess.asp] Accessed 7/1/11 also see: Low, B., Davidson, Z., Parker, G., Sundaresan, S., Fischer, M. and Lalampaa, P. (2010) Reassessing the status of Grevy’s zebra (Equus grevyi), and other large mammals in the Marsabit region of northern Kenya. Preliminary report. Available online at: http://www.marwell.org.uk/conservation/programmes/populations.asp. 13 Marwell Wildlife (2010) Award win for sustainable business. [http://www.marwell.org.uk/SustainableBusinessAwardWin.asp] Accessed 7/1/11 14 Marwell Wildlife Review of the year available online at http://www.marwell.org.uk/behind_the_scenes/annual_review/default.asp?css=1 Wildlife Conservation 15 EAZA (unknown) About Eaza [http://www.eaza.net/about/Pages/Introduction.aspx] Accessed 8/4/10 16 For more details on the work of BIAZA see www.biaza.org. 17 Web address for conservation resources: http://www.marwell.org.uk/conservation/resources/Resources.asp?css=1 18 Web address for population management programmes: http://www.marwell.org.uk/conservation/programmes/populations.asp. 19 Durant, S., Marker, L., Purchase, N., Belbachir, F., Hunter, L., Packer, C., Breitenmoser-Wursten, C., Sogbohossou, E. & Bauer, H. 2008. Acinonyx jubatus. In: IUCN 2010. IUCN Red List of Threatened Species. Version 2010.4. [www.iucnredlist.org/apps/redlist/details/219/0] Accessed 7/4/10 Wildlife Conservation